Source code of Windows XP (NT5)
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/*++
Copyright (c) 1989 Microsoft Corporation
Module Name:
miglobal.c
Abstract:
This module contains the private global storage for the memory
management subsystem.
Author:
Lou Perazzoli (loup) 6-Apr-1989
Landy Wang (landyw) 02-June-1997
Revision History:
--*/
#include "mi.h"
//
// Highest user address;
//
PVOID MmHighestUserAddress;
//
// Start of system address range.
//
PVOID MmSystemRangeStart;
//
// User probe address;
//
ULONG_PTR MmUserProbeAddress;
#if !defined(_WIN64)
//
// Virtual bias applied during the loading of the kernel image.
//
ULONG_PTR MmVirtualBias;
#endif
//
// Number of secondary colors, based on level 2 d cache size.
//
ULONG MmSecondaryColors;
//
// The starting color index seed, incremented at each process creation.
//
ULONG MmProcessColorSeed = 0x12345678;
//
// Total number of physical pages available on the system.
//
PFN_COUNT MmNumberOfPhysicalPages;
//
// Lowest physical page number in the system.
//
PFN_NUMBER MmLowestPhysicalPage = (PFN_NUMBER)-1;
//
// Highest physical page number in the system.
//
PFN_NUMBER MmHighestPhysicalPage;
//
// Highest possible physical page number in the system.
//
PFN_NUMBER MmHighestPossiblePhysicalPage;
//
// Total number of available pages in the system. This
// is the sum of the pages on the zeroed, free and standby lists.
//
PFN_COUNT MmAvailablePages;
PFN_NUMBER MmThrottleTop;
PFN_NUMBER MmThrottleBottom;
//
// Highest VAD index used to create bitmaps.
//
ULONG MiLastVadBit = 1;
//
// System wide memory management statistics block.
//
MMINFO_COUNTERS MmInfoCounters;
//
// Total number of physical pages which would be usable if every process
// was at its minimum working set size. This value is initialized
// at system initialization to MmAvailablePages - MM_FLUID_PHYSICAL_PAGES.
// Every time a thread is created, the kernel stack is subtracted from
// this and every time a process is created, the minimum working set
// is subtracted from this. If the value would become negative, the
// operation (create process/kernel stack/ adjust working set) fails.
// The PFN LOCK must be owned to manipulate this value.
//
SPFN_NUMBER MmResidentAvailablePages;
//
// The total number of pages which would be removed from working sets
// if every working set was at its minimum.
//
PFN_NUMBER MmPagesAboveWsMinimum;
//
// The total number of pages which would be removed from working sets
// if every working set above its maximum was at its maximum.
//
PFN_NUMBER MmPagesAboveWsMaximum;
//
// The number of pages to add to a working set if there are ample
// available pages and the working set is below its maximum.
//
//
// If memory is becoming short and MmPagesAboveWsMinimum is
// greater than MmPagesAboveWsThreshold, trim working sets.
//
PFN_NUMBER MmPagesAboveWsThreshold = 37;
PFN_NUMBER MmWorkingSetSizeIncrement = 6;
//
// The number of pages to extend the maximum working set size by
// if the working set at its maximum and there are ample available pages.
PFN_NUMBER MmWorkingSetSizeExpansion = 20;
//
// The number of pages required to be freed by working set reduction
// before working set reduction is attempted.
//
PFN_NUMBER MmWsAdjustThreshold = 45;
//
// The number of pages available to allow the working set to be
// expanded above its maximum.
//
PFN_NUMBER MmWsExpandThreshold = 90;
//
// The total number of pages to reduce by working set trimming.
//
PFN_NUMBER MmWsTrimReductionGoal = 29;
//
// The total number of pages needed for the loader to successfully hibernate.
//
PFN_NUMBER MmHiberPages = 768;
//
// The following values are frequently used together. They tend
// not to be modified once the system has initialized so should
// not be grouped with data whose values change frequently to
// eliminate false sharing.
//
ULONG MmSecondaryColorMask;
UCHAR MmSecondaryColorNodeShift;
//
// Registry-settable threshold for using large pages. x86 only.
//
ULONG MmLargePageMinimum;
PMMPFN MmPfnDatabase;
MMPFNLIST MmZeroedPageListHead = {
0, // Total
ZeroedPageList, // ListName
MM_EMPTY_LIST, //Flink
MM_EMPTY_LIST // Blink
};
MMPFNLIST MmFreePageListHead = {
0, // Total
FreePageList, // ListName
MM_EMPTY_LIST, //Flink
MM_EMPTY_LIST // Blink
};
MMPFNLIST MmStandbyPageListHead = {
0, // Total
StandbyPageList, // ListName
MM_EMPTY_LIST, //Flink
MM_EMPTY_LIST // Blink
};
MMPFNLIST MmModifiedPageListHead = {
0, // Total
ModifiedPageList, // ListName
MM_EMPTY_LIST, //Flink
MM_EMPTY_LIST // Blink
};
MMPFNLIST MmModifiedNoWritePageListHead = {
0, // Total
ModifiedNoWritePageList, // ListName
MM_EMPTY_LIST, //Flink
MM_EMPTY_LIST // Blink
};
MMPFNLIST MmBadPageListHead = {
0, // Total
BadPageList, // ListName
MM_EMPTY_LIST, //Flink
MM_EMPTY_LIST // Blink
};
//
// Note the ROM page listhead is deliberately not in the set
// of MmPageLocationList ranges.
//
MMPFNLIST MmRomPageListHead = {
0, // Total
StandbyPageList, // ListName
MM_EMPTY_LIST, //Flink
MM_EMPTY_LIST // Blink
};
PMMPFNLIST MmPageLocationList[NUMBER_OF_PAGE_LISTS] = {
&MmZeroedPageListHead,
&MmFreePageListHead,
&MmStandbyPageListHead,
&MmModifiedPageListHead,
&MmModifiedNoWritePageListHead,
&MmBadPageListHead,
NULL,
NULL };
PMMPTE MiHighestUserPte;
PMMPTE MiHighestUserPde;
#if (_MI_PAGING_LEVELS >= 4)
PMMPTE MiHighestUserPpe;
PMMPTE MiHighestUserPxe;
#endif
PMMPTE MiSessionBasePte;
PMMPTE MiSessionLastPte;
//
// Hyper space items.
//
PMMPTE MmFirstReservedMappingPte;
PMMPTE MmLastReservedMappingPte;
//
// Event for available pages, set means pages are available.
//
KEVENT MmAvailablePagesEvent;
//
// Event for the zeroing page thread.
//
KEVENT MmZeroingPageEvent;
//
// Boolean to indicate if the zeroing page thread is currently
// active. This is set to true when the zeroing page event is
// set and set to false when the zeroing page thread is done
// zeroing all the pages on the free list.
//
BOOLEAN MmZeroingPageThreadActive;
//
// Minimum number of free pages before zeroing page thread starts.
//
PFN_NUMBER MmMinimumFreePagesToZero = 8;
//
// System space sizes - MmNonPagedSystemStart to MM_NON_PAGED_SYSTEM_END
// defines the ranges of PDEs which must be copied into a new process's
// address space.
//
PVOID MmNonPagedSystemStart;
LOGICAL MmProtectFreedNonPagedPool;
//
// This is set in the registry to the maximum number of gigabytes of RAM
// that can be added to this machine (ie: #of DIMM slots times maximum
// supported DIMM size). This lets configurations that won't use the absolute
// maximum indicate that a smaller (virtually) PFN database size can be used
// thus leaving more virtual address space for things like system PTEs, etc.
//
PFN_NUMBER MmDynamicPfn;
#ifdef MM_BUMP_COUNTER_MAX
SIZE_T MmResTrack[MM_BUMP_COUNTER_MAX];
#endif
#ifdef MM_COMMIT_COUNTER_MAX
SIZE_T MmTrackCommit[MM_COMMIT_COUNTER_MAX];
#endif
//
// Set via the registry to identify which drivers are leaking locked pages.
//
LOGICAL MmTrackLockedPages;
KSPIN_LOCK MiTrackLockedPagesLock;
//
// Set via the registry to identify drivers which unload without releasing
// resources or still have active timers, etc.
//
LOGICAL MmSnapUnloads = TRUE;
#if DBG
PETHREAD MiExpansionLockOwner;
#endif
//
// Pool sizes.
//
SIZE_T MmSizeOfNonPagedPoolInBytes;
SIZE_T MmMaximumNonPagedPoolInBytes;
ULONG MmMaximumNonPagedPoolPercent;
SIZE_T MmMinimumNonPagedPoolSize = 256 * 1024; // 256k
ULONG MmMinAdditionNonPagedPoolPerMb = 32 * 1024; // 32k
SIZE_T MmDefaultMaximumNonPagedPool = 1024 * 1024; // 1mb
ULONG MmMaxAdditionNonPagedPoolPerMb = 400 * 1024; //400k
SIZE_T MmSizeOfPagedPoolInBytes = 32 * 1024 * 1024; // 32 MB.
ULONG MmNumberOfSystemPtes;
ULONG MiRequestedSystemPtes;
PMMPTE MmFirstPteForPagedPool;
PMMPTE MmLastPteForPagedPool;
//
// Pool bit maps and other related structures.
//
PVOID MmPageAlignedPoolBase[2];
ULONG MmExpandedPoolBitPosition;
PFN_NUMBER MmNumberOfFreeNonPagedPool;
//
// MmFirstFreeSystemPte contains the offset from the
// Nonpaged system base to the first free system PTE.
// Note that an offset of -1 indicates an empty list.
//
MMPTE MmFirstFreeSystemPte[MaximumPtePoolTypes];
//
// System cache sizes.
//
PMMWSL MmSystemCacheWorkingSetList = (PMMWSL)MM_SYSTEM_CACHE_WORKING_SET;
MMSUPPORT MmSystemCacheWs;
PMMWSLE MmSystemCacheWsle;
PVOID MmSystemCacheStart = (PVOID)MM_SYSTEM_CACHE_START;
PVOID MmSystemCacheEnd;
PRTL_BITMAP MmSystemCacheAllocationMap;
PRTL_BITMAP MmSystemCacheEndingMap;
//
// This value should not be greater than 256MB in a system with 1GB of
// system space.
//
ULONG_PTR MmSizeOfSystemCacheInPages = 64 * 256; //64MB.
//
// Default sizes for the system cache.
//
PFN_NUMBER MmSystemCacheWsMinimum = 288;
PFN_NUMBER MmSystemCacheWsMaximum = 350;
//
// Cells to track unused thread kernel stacks to avoid TB flushes
// every time a thread terminates.
//
ULONG MmMaximumDeadKernelStacks = 5;
SLIST_HEADER MmDeadStackSListHead;
//
// Cells to track control area synchronization.
//
SLIST_HEADER MmEventCountSListHead;
SLIST_HEADER MmInPageSupportSListHead;
//
// MmSystemPteBase contains the address of 1 PTE before
// the first free system PTE (zero indicates an empty list).
// The value of this field does not change once set.
//
PMMPTE MmSystemPteBase;
PMMADDRESS_NODE MmSectionBasedRoot;
PVOID MmHighSectionBase;
//
// Section object type.
//
POBJECT_TYPE MmSectionObjectType;
//
// Section commit mutex.
//
FAST_MUTEX MmSectionCommitMutex;
//
// Section base address mutex.
//
FAST_MUTEX MmSectionBasedMutex;
//
// Resource for section extension.
//
ERESOURCE MmSectionExtendResource;
ERESOURCE MmSectionExtendSetResource;
//
// Pagefile creation lock.
//
FAST_MUTEX MmPageFileCreationLock;
MMDEREFERENCE_SEGMENT_HEADER MmDereferenceSegmentHeader;
LIST_ENTRY MmUnusedSegmentList;
LIST_ENTRY MmUnusedSubsectionList;
KEVENT MmUnusedSegmentCleanup;
ULONG MmUnusedSegmentCount;
ULONG MmUnusedSubsectionCount;
ULONG MmUnusedSubsectionCountPeak;
SIZE_T MiUnusedSubsectionPagedPool;
SIZE_T MiUnusedSubsectionPagedPoolPeak;
//
// If more than this percentage of pool is consumed and pool allocations
// might fail, then trim unused segments & subsections to get back to
// this percentage.
//
ULONG MmConsumedPoolPercentage;
MMWORKING_SET_EXPANSION_HEAD MmWorkingSetExpansionHead;
MMPAGE_FILE_EXPANSION MmAttemptForCantExtend;
//
// Paging files
//
MMMOD_WRITER_LISTHEAD MmPagingFileHeader;
MMMOD_WRITER_LISTHEAD MmMappedFileHeader;
LIST_ENTRY MmFreePagingSpaceLow;
ULONG MmNumberOfActiveMdlEntries;
PMMPAGING_FILE MmPagingFile[MAX_PAGE_FILES];
ULONG MmNumberOfPagingFiles;
KEVENT MmModifiedPageWriterEvent;
KEVENT MmWorkingSetManagerEvent;
KEVENT MmCollidedFlushEvent;
//
// Total number of committed pages.
//
SIZE_T MmTotalCommittedPages;
//
// Limit on committed pages. When MmTotalCommittedPages would become
// greater than or equal to this number the paging files must be expanded.
//
SIZE_T MmTotalCommitLimit;
SIZE_T MmTotalCommitLimitMaximum;
//
// Number of pages to overcommit without expanding the paging file.
// MmTotalCommitLimit = (total paging file space) + MmOverCommit.
//
SIZE_T MmOverCommit;
//
// Modified page writer.
//
//
// Minimum number of free pages before working set trimming and
// aggressive modified page writing is started.
//
PFN_NUMBER MmMinimumFreePages = 26;
//
// Stop writing modified pages when MmFreeGoal pages exist.
//
PFN_NUMBER MmFreeGoal = 100;
//
// Start writing pages if more than this number of pages
// is on the modified page list.
//
PFN_NUMBER MmModifiedPageMaximum;
//
// Minimum number of modified pages required before the modified
// page writer is started.
//
PFN_NUMBER MmModifiedPageMinimum;
//
// Amount of disk space that must be free after the paging file is
// extended.
//
ULONG MmMinimumFreeDiskSpace = 1024 * 1024;
//
// Minimum size in pages to extend the paging file by.
//
ULONG MmPageFileExtension = 256;
//
// Size to reduce the paging file by.
//
ULONG MmMinimumPageFileReduction = 256; //256 pages (1mb)
//
// Number of pages to write in a single I/O.
//
ULONG MmModifiedWriteClusterSize = MM_MAXIMUM_WRITE_CLUSTER;
//
// Number of pages to read in a single I/O if possible.
//
ULONG MmReadClusterSize = 7;
const ULONG MMSECT = 'tSmM'; // This is exported to special pool.
//
// This resource guards the working set list for the system shared
// address space (paged pool, system cache, pagable drivers).
//
ERESOURCE MmSystemWsLock;
PETHREAD MmSystemLockOwner;
//
// Spin lock for allowing working set expansion.
//
KSPIN_LOCK MmExpansionLock;
//
// System process working set sizes.
//
PFN_NUMBER MmSystemProcessWorkingSetMin = 50;
PFN_NUMBER MmSystemProcessWorkingSetMax = 450;
WSLE_NUMBER MmMaximumWorkingSetSize;
PFN_NUMBER MmMinimumWorkingSetSize = 20;
//
// Page color for system working set.
//
ULONG MmSystemPageColor;
//
// Time constants
//
const LARGE_INTEGER MmSevenMinutes = {0, -1};
//
// Note that the following constant is initialized to five seconds,
// but is set to 3 on very small workstations.
//
LARGE_INTEGER MmWorkingSetProtectionTime = {5 * 1000 * 1000 * 10, 0};
const LARGE_INTEGER MmOneSecond = {(ULONG)(-1 * 1000 * 1000 * 10), -1};
const LARGE_INTEGER MmTwentySeconds = {(ULONG)(-20 * 1000 * 1000 * 10), -1};
const LARGE_INTEGER MmShortTime = {(ULONG)(-10 * 1000 * 10), -1}; // 10 milliseconds
const LARGE_INTEGER MmHalfSecond = {(ULONG)(-5 * 100 * 1000 * 10), -1};
const LARGE_INTEGER Mm30Milliseconds = {(ULONG)(-30 * 1000 * 10), -1};
//
// Parameters for user mode passed up via PEB in MmCreatePeb.
//
LARGE_INTEGER MmCriticalSectionTimeout; // Filled in by mminit.c
SIZE_T MmHeapSegmentReserve = 1024 * 1024;
SIZE_T MmHeapSegmentCommit = PAGE_SIZE * 2;
SIZE_T MmHeapDeCommitTotalFreeThreshold = 64 * 1024;
SIZE_T MmHeapDeCommitFreeBlockThreshold = PAGE_SIZE;
//
// Set from ntos\config\CMDAT3.C Used by customers to disable paging
// of executive on machines with lots of memory. Worth a few TPS on a
// database server.
//
ULONG MmDisablePagingExecutive;
BOOLEAN Mm64BitPhysicalAddress;
#if DBG
ULONG MmDebug;
#endif
//
// Map a page protection from the Pte.Protect field into a protection mask.
//
ULONG MmProtectToValue[32] = {
PAGE_NOACCESS,
PAGE_READONLY,
PAGE_EXECUTE,
PAGE_EXECUTE_READ,
PAGE_READWRITE,
PAGE_WRITECOPY,
PAGE_EXECUTE_READWRITE,
PAGE_EXECUTE_WRITECOPY,
PAGE_NOACCESS,
PAGE_NOCACHE | PAGE_READONLY,
PAGE_NOCACHE | PAGE_EXECUTE,
PAGE_NOCACHE | PAGE_EXECUTE_READ,
PAGE_NOCACHE | PAGE_READWRITE,
PAGE_NOCACHE | PAGE_WRITECOPY,
PAGE_NOCACHE | PAGE_EXECUTE_READWRITE,
PAGE_NOCACHE | PAGE_EXECUTE_WRITECOPY,
PAGE_NOACCESS,
PAGE_GUARD | PAGE_READONLY,
PAGE_GUARD | PAGE_EXECUTE,
PAGE_GUARD | PAGE_EXECUTE_READ,
PAGE_GUARD | PAGE_READWRITE,
PAGE_GUARD | PAGE_WRITECOPY,
PAGE_GUARD | PAGE_EXECUTE_READWRITE,
PAGE_GUARD | PAGE_EXECUTE_WRITECOPY,
PAGE_NOACCESS,
PAGE_NOCACHE | PAGE_GUARD | PAGE_READONLY,
PAGE_NOCACHE | PAGE_GUARD | PAGE_EXECUTE,
PAGE_NOCACHE | PAGE_GUARD | PAGE_EXECUTE_READ,
PAGE_NOCACHE | PAGE_GUARD | PAGE_READWRITE,
PAGE_NOCACHE | PAGE_GUARD | PAGE_WRITECOPY,
PAGE_NOCACHE | PAGE_GUARD | PAGE_EXECUTE_READWRITE,
PAGE_NOCACHE | PAGE_GUARD | PAGE_EXECUTE_WRITECOPY
};
#if (defined(_WIN64) || defined(_X86PAE_))
ULONGLONG
#else
ULONG
#endif
MmProtectToPteMask[32] = {
MM_PTE_NOACCESS,
MM_PTE_READONLY | MM_PTE_CACHE,
MM_PTE_EXECUTE | MM_PTE_CACHE,
MM_PTE_EXECUTE_READ | MM_PTE_CACHE,
MM_PTE_READWRITE | MM_PTE_CACHE,
MM_PTE_WRITECOPY | MM_PTE_CACHE,
MM_PTE_EXECUTE_READWRITE | MM_PTE_CACHE,
MM_PTE_EXECUTE_WRITECOPY | MM_PTE_CACHE,
MM_PTE_NOACCESS,
MM_PTE_NOCACHE | MM_PTE_READONLY,
MM_PTE_NOCACHE | MM_PTE_EXECUTE,
MM_PTE_NOCACHE | MM_PTE_EXECUTE_READ,
MM_PTE_NOCACHE | MM_PTE_READWRITE,
MM_PTE_NOCACHE | MM_PTE_WRITECOPY,
MM_PTE_NOCACHE | MM_PTE_EXECUTE_READWRITE,
MM_PTE_NOCACHE | MM_PTE_EXECUTE_WRITECOPY,
MM_PTE_NOACCESS,
MM_PTE_GUARD | MM_PTE_READONLY | MM_PTE_CACHE,
MM_PTE_GUARD | MM_PTE_EXECUTE | MM_PTE_CACHE,
MM_PTE_GUARD | MM_PTE_EXECUTE_READ | MM_PTE_CACHE,
MM_PTE_GUARD | MM_PTE_READWRITE | MM_PTE_CACHE,
MM_PTE_GUARD | MM_PTE_WRITECOPY | MM_PTE_CACHE,
MM_PTE_GUARD | MM_PTE_EXECUTE_READWRITE | MM_PTE_CACHE,
MM_PTE_GUARD | MM_PTE_EXECUTE_WRITECOPY | MM_PTE_CACHE,
MM_PTE_NOACCESS,
MM_PTE_NOCACHE | MM_PTE_GUARD | MM_PTE_READONLY,
MM_PTE_NOCACHE | MM_PTE_GUARD | MM_PTE_EXECUTE,
MM_PTE_NOCACHE | MM_PTE_GUARD | MM_PTE_EXECUTE_READ,
MM_PTE_NOCACHE | MM_PTE_GUARD | MM_PTE_READWRITE,
MM_PTE_NOCACHE | MM_PTE_GUARD | MM_PTE_WRITECOPY,
MM_PTE_NOCACHE | MM_PTE_GUARD | MM_PTE_EXECUTE_READWRITE,
MM_PTE_NOCACHE | MM_PTE_GUARD | MM_PTE_EXECUTE_WRITECOPY
};
//
// Conversion which takes a Pte.Protect and builds a new Pte.Protect which
// is not copy-on-write.
//
ULONG MmMakeProtectNotWriteCopy[32] = {
MM_NOACCESS,
MM_READONLY,
MM_EXECUTE,
MM_EXECUTE_READ,
MM_READWRITE,
MM_READWRITE, //not copy
MM_EXECUTE_READWRITE,
MM_EXECUTE_READWRITE,
MM_NOACCESS,
MM_NOCACHE | MM_READONLY,
MM_NOCACHE | MM_EXECUTE,
MM_NOCACHE | MM_EXECUTE_READ,
MM_NOCACHE | MM_READWRITE,
MM_NOCACHE | MM_READWRITE,
MM_NOCACHE | MM_EXECUTE_READWRITE,
MM_NOCACHE | MM_EXECUTE_READWRITE,
MM_NOACCESS,
MM_GUARD_PAGE | MM_READONLY,
MM_GUARD_PAGE | MM_EXECUTE,
MM_GUARD_PAGE | MM_EXECUTE_READ,
MM_GUARD_PAGE | MM_READWRITE,
MM_GUARD_PAGE | MM_READWRITE,
MM_GUARD_PAGE | MM_EXECUTE_READWRITE,
MM_GUARD_PAGE | MM_EXECUTE_READWRITE,
MM_NOACCESS,
MM_NOCACHE | MM_GUARD_PAGE | MM_READONLY,
MM_NOCACHE | MM_GUARD_PAGE | MM_EXECUTE,
MM_NOCACHE | MM_GUARD_PAGE | MM_EXECUTE_READ,
MM_NOCACHE | MM_GUARD_PAGE | MM_READWRITE,
MM_NOCACHE | MM_GUARD_PAGE | MM_READWRITE,
MM_NOCACHE | MM_GUARD_PAGE | MM_EXECUTE_READWRITE,
MM_NOCACHE | MM_GUARD_PAGE | MM_EXECUTE_READWRITE
};
//
// Converts a protection code to an access right for section access.
// This uses only the lower 3 bits of the 5 bit protection code.
//
ACCESS_MASK MmMakeSectionAccess[8] = { SECTION_MAP_READ,
SECTION_MAP_READ,
SECTION_MAP_EXECUTE,
SECTION_MAP_EXECUTE | SECTION_MAP_READ,
SECTION_MAP_WRITE,
SECTION_MAP_READ,
SECTION_MAP_EXECUTE | SECTION_MAP_WRITE,
SECTION_MAP_EXECUTE | SECTION_MAP_READ };
//
// Converts a protection code to an access right for file access.
// This uses only the lower 3 bits of the 5 bit protection code.
//
ACCESS_MASK MmMakeFileAccess[8] = { FILE_READ_DATA,
FILE_READ_DATA,
FILE_EXECUTE,
FILE_EXECUTE | FILE_READ_DATA,
FILE_WRITE_DATA | FILE_READ_DATA,
FILE_READ_DATA,
FILE_EXECUTE | FILE_WRITE_DATA | FILE_READ_DATA,
FILE_EXECUTE | FILE_READ_DATA };
MM_PAGED_POOL_INFO MmPagedPoolInfo;
//
// Some Hydra variables.
//
ULONG_PTR MmSessionBase;
PMM_SESSION_SPACE MmSessionSpace;
ULONG_PTR MiSessionSpaceWs;
SIZE_T MmSessionSize;
LIST_ENTRY MiSessionWsList;
ULONG_PTR MiSystemViewStart;
SIZE_T MmSystemViewSize;
ULONG_PTR MiSessionPoolStart;
ULONG_PTR MiSessionPoolEnd;
ULONG_PTR MiSessionSpaceEnd;
ULONG_PTR MiSessionViewStart;
ULONG MiSessionSpacePageTables;
SIZE_T MmSessionViewSize;
SIZE_T MmSessionPoolSize;
ULONG_PTR MiSessionImageStart;
ULONG_PTR MiSessionImageEnd;
PMMPTE MiSessionImagePteStart;
PMMPTE MiSessionImagePteEnd;
SIZE_T MmSessionImageSize;
//
// Cache control stuff. Note this may be overridden by deficient hardware
// platforms at startup.
//
MI_PFN_CACHE_ATTRIBUTE MiPlatformCacheAttributes[2 * MmMaximumCacheType] =
{
//
// Memory space
//
MiNonCached,
MiCached,
MiWriteCombined,
MiCached,
MiNonCached,
MiWriteCombined,
//
// I/O space
//
MiNonCached,
MiCached,
MiWriteCombined,
MiCached,
MiNonCached,
MiWriteCombined
};
//
// Note the Driver Verifier can reinitialize the mask values.
//
ULONG MiIoRetryMask = 0x1f;
ULONG MiFaultRetryMask = 0x1f;
ULONG MiUserFaultRetryMask = 0xF;
#if defined (_MI_INSTRUMENT_PFN)
//
// Instrumentation code to track PFN lock duration.
//
ULONG MiPfnTimings;
ULONG_PTR MiPfnAcquiredAddress;
LARGE_INTEGER MiPfnAcquired;
LARGE_INTEGER MiPfnThreshold;
MMPFNTIMINGS MiPfnSorted[MI_MAX_PFN_CALLERS];
ULONG MiMaxPfnTimings = MI_MAX_PFN_CALLERS;
ULONG_PTR
MiGetExecutionAddress(
VOID
)
{
#if defined(_X86_)
_asm {
push dword ptr [esp]
pop eax
}
#else
PVOID CallingAddress;
PVOID CallersCaller;
RtlGetCallersAddress (&CallingAddress, &CallersCaller);
return (ULONG_PTR) CallingAddress;
#endif
}
#endif
#ifdef ALLOC_DATA_PRAGMA
#pragma data_seg("INIT")
#endif
WCHAR MmVerifyDriverBuffer[MI_SUSPECT_DRIVER_BUFFER_LENGTH] = {0};
ULONG MmVerifyDriverBufferType = REG_NONE;
ULONG MmVerifyDriverLevel = (ULONG)-1;
ULONG MmCritsectTimeoutSeconds = 2592000;
#ifdef ALLOC_DATA_PRAGMA
#pragma data_seg()
#endif
ULONG MmVerifyDriverBufferLength = sizeof(MmVerifyDriverBuffer);